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1.1 ! root 1: /* Copyright (c) 1982 Regents of the University of California */ ! 2: ! 3: static char sccsid[] = "@(#)tree.c 1.6 2/15/83"; ! 4: ! 5: /* ! 6: * This module contains the interface between the SYM routines and ! 7: * the parse tree routines. It would be nice if such a crude ! 8: * interface were not necessary, but some parts of tree building are ! 9: * language and hence SYM-representation dependent. It's probably ! 10: * better to have tree-representation dependent code here than vice versa. ! 11: */ ! 12: ! 13: #include "defs.h" ! 14: #include "tree.h" ! 15: #include "sym.h" ! 16: #include "btypes.h" ! 17: #include "classes.h" ! 18: #include "sym.rep" ! 19: #include "tree/tree.rep" ! 20: ! 21: typedef char *ARGLIST; ! 22: ! 23: #define nextarg(arglist, type) ((type *) (arglist += sizeof(type)))[-1] ! 24: ! 25: LOCAL SYM *mkstring(); ! 26: LOCAL SYM *namenode(); ! 27: ! 28: /* ! 29: * Determine the type of a parse tree. While we're at, check ! 30: * the parse tree out. ! 31: */ ! 32: ! 33: SYM *treetype(p, ap) ! 34: register NODE *p; ! 35: register ARGLIST ap; ! 36: { ! 37: switch(p->op) { ! 38: case O_NAME: { ! 39: SYM *s; ! 40: ! 41: s = nextarg(ap, SYM *); ! 42: s = which(s); ! 43: return namenode(p, s); ! 44: /* NOTREACHED */ ! 45: } ! 46: ! 47: case O_WHICH: ! 48: p->nameval = nextarg(ap, SYM *); ! 49: p->nameval = which(p->nameval); ! 50: return NIL; ! 51: ! 52: case O_LCON: ! 53: return t_int; ! 54: ! 55: case O_FCON: ! 56: return t_real; ! 57: ! 58: case O_SCON: { ! 59: char *cpy; ! 60: SYM *s; ! 61: ! 62: cpy = strdup(p->sconval); ! 63: p->sconval = cpy; ! 64: s = mkstring(p->sconval); ! 65: if (s == t_char) { ! 66: p->op = O_LCON; ! 67: p->lconval = p->sconval[0]; ! 68: } ! 69: return s; ! 70: } ! 71: ! 72: case O_INDIR: ! 73: p->left = nextarg(ap, NODE *); ! 74: chkclass(p->left, PTR); ! 75: return rtype(p->left->nodetype)->type; ! 76: ! 77: case O_RVAL: { ! 78: NODE *p1, *q; ! 79: ! 80: p1 = p->left; ! 81: p->nodetype = p1->nodetype; ! 82: if (p1->op == O_NAME) { ! 83: if (p1->nodetype->class == FUNC) { ! 84: p->op = O_CALL; ! 85: p->right = NIL; ! 86: } else if (p1->nameval->class == CONST) { ! 87: if (p1->nameval->type == t_real->type) { ! 88: p->op = O_FCON; ! 89: p->fconval = p1->nameval->symvalue.fconval; ! 90: p->nodetype = t_real; ! 91: dispose(p1); ! 92: } else { ! 93: p->op = O_LCON; ! 94: p->lconval = p1->nameval->symvalue.iconval; ! 95: p->nodetype = p1->nameval->type; ! 96: dispose(p1); ! 97: } ! 98: } ! 99: } ! 100: return p->nodetype; ! 101: /* NOTREACHED */ ! 102: } ! 103: ! 104: case O_CALL: { ! 105: SYM *s; ! 106: ! 107: p->left = nextarg(ap, NODE *); ! 108: p->right = nextarg(ap, NODE *); ! 109: s = p->left->nodetype; ! 110: if (isblock(s) && isbuiltin(s)) { ! 111: p->op = (OP) s->symvalue.token.tokval; ! 112: tfree(p->left); ! 113: p->left = p->right; ! 114: p->right = NIL; ! 115: } ! 116: return s->type; ! 117: } ! 118: ! 119: case O_ITOF: ! 120: return t_real; ! 121: ! 122: case O_NEG: { ! 123: SYM *s; ! 124: ! 125: p->left = nextarg(ap, NODE *); ! 126: s = p->left->nodetype; ! 127: if (!compatible(s, t_int)) { ! 128: if (!compatible(s, t_real)) { ! 129: trerror("%t is improper type", p->left); ! 130: } else { ! 131: p->op = O_NEGF; ! 132: } ! 133: } ! 134: return s; ! 135: } ! 136: ! 137: case O_ADD: ! 138: case O_SUB: ! 139: case O_MUL: ! 140: case O_LT: ! 141: case O_LE: ! 142: case O_GT: ! 143: case O_GE: ! 144: case O_EQ: ! 145: case O_NE: ! 146: { ! 147: BOOLEAN t1real, t2real; ! 148: SYM *t1, *t2; ! 149: ! 150: p->left = nextarg(ap, NODE *); ! 151: p->right = nextarg(ap, NODE *); ! 152: t1 = rtype(p->left->nodetype); ! 153: t2 = rtype(p->right->nodetype); ! 154: t1real = (t1 == t_real); ! 155: t2real = (t2 == t_real); ! 156: if (t1real || t2real) { ! 157: p->op++; ! 158: if (!t1real) { ! 159: p->left = build(O_ITOF, p->left); ! 160: } else if (!t2real) { ! 161: p->right = build(O_ITOF, p->right); ! 162: } ! 163: } else { ! 164: if (t1real) { ! 165: convert(&p->left, t_int, O_NOP); ! 166: } ! 167: if (t2real) { ! 168: convert(&p->right, t_int, O_NOP); ! 169: } ! 170: } ! 171: if (p->op >= O_LT) { ! 172: return t_boolean; ! 173: } else { ! 174: if (t1real || t2real) { ! 175: return t_real; ! 176: } else { ! 177: return t_int; ! 178: } ! 179: } ! 180: /* NOTREACHED */ ! 181: } ! 182: ! 183: case O_DIVF: ! 184: p->left = nextarg(ap, NODE *); ! 185: p->right = nextarg(ap, NODE *); ! 186: convert(&p->left, t_real, O_ITOF); ! 187: convert(&p->right, t_real, O_ITOF); ! 188: return t_real; ! 189: ! 190: case O_DIV: ! 191: case O_MOD: ! 192: p->left = nextarg(ap, NODE *); ! 193: p->right = nextarg(ap, NODE *); ! 194: convert(&p->left, t_int, O_NOP); ! 195: convert(&p->right, t_int, O_NOP); ! 196: return t_int; ! 197: ! 198: case O_AND: ! 199: case O_OR: ! 200: p->left = nextarg(ap, NODE *); ! 201: p->right = nextarg(ap, NODE *); ! 202: chkboolean(p->left); ! 203: chkboolean(p->right); ! 204: return t_boolean; ! 205: ! 206: default: ! 207: return NIL; ! 208: } ! 209: } ! 210: ! 211: /* ! 212: * Create a node for a name. The symbol for the name has already ! 213: * been chosen, either implicitly with "which" or explicitly from ! 214: * the dot routine. ! 215: */ ! 216: ! 217: LOCAL SYM *namenode(p, s) ! 218: NODE *p; ! 219: SYM *s; ! 220: { ! 221: NODE *np; ! 222: ! 223: p->nameval = s; ! 224: if (s->class == REF) { ! 225: np = alloc(1, NODE); ! 226: *np = *p; ! 227: p->op = O_INDIR; ! 228: p->left = np; ! 229: np->nodetype = s; ! 230: } ! 231: if (s->class == CONST || s->class == VAR || s->class == FVAR) { ! 232: return s->type; ! 233: } else { ! 234: return s; ! 235: } ! 236: } ! 237: ! 238: /* ! 239: * Convert a tree to a type via a conversion operator; ! 240: * if this isn't possible generate an error. ! 241: * ! 242: * Note the tree is call by address, hence the #define below. ! 243: */ ! 244: ! 245: LOCAL convert(tp, typeto, op) ! 246: NODE **tp; ! 247: SYM *typeto; ! 248: OP op; ! 249: { ! 250: #define tree (*tp) ! 251: ! 252: SYM *s; ! 253: ! 254: s = rtype(tree->nodetype); ! 255: typeto = rtype(typeto); ! 256: if (typeto == t_real && compatible(s, t_int)) { ! 257: tree = build(op, tree); ! 258: } else if (!compatible(s, typeto)) { ! 259: trerror("%t is improper type"); ! 260: } else if (op != O_NOP && s != typeto) { ! 261: tree = build(op, tree); ! 262: } ! 263: ! 264: #undef tree ! 265: } ! 266: ! 267: /* ! 268: * Construct a node for the Pascal dot operator. ! 269: * ! 270: * If the left operand is not a record, but rather a procedure ! 271: * or function, then we interpret the "." as referencing an ! 272: * "invisible" variable; i.e. a variable within a dynamically ! 273: * active block but not within the static scope of the current procedure. ! 274: */ ! 275: ! 276: NODE *dot(record, field) ! 277: NODE *record; ! 278: SYM *field; ! 279: { ! 280: register NODE *p; ! 281: register SYM *s; ! 282: ! 283: if (isblock(record->nodetype)) { ! 284: s = findsym(field, record->nodetype); ! 285: if (s == NIL) { ! 286: error("\"%s\" is not defined in \"%s\"", ! 287: field->symbol, record->nodetype->symbol); ! 288: } ! 289: p = alloc(1, NODE); ! 290: p->op = O_NAME; ! 291: p->nodetype = namenode(p, s); ! 292: } else { ! 293: s = findclass(field, FIELD); ! 294: if (s == NIL) { ! 295: error("\"%s\" is not a field", field->symbol); ! 296: } ! 297: field = s; ! 298: chkfield(record, field); ! 299: p = alloc(1, NODE); ! 300: p->op = O_ADD; ! 301: p->nodetype = field->type; ! 302: p->left = record; ! 303: p->right = build(O_LCON, (long) field->symvalue.offset); ! 304: } ! 305: return p; ! 306: } ! 307: ! 308: /* ! 309: * Return a tree corresponding to an array reference and do the ! 310: * error checking. ! 311: */ ! 312: ! 313: NODE *subscript(a, slist) ! 314: NODE *a, *slist; ! 315: { ! 316: register SYM *t; ! 317: register NODE *p; ! 318: SYM *etype, *atype, *eltype; ! 319: NODE *esub; ! 320: ! 321: t = rtype(a->nodetype); ! 322: if (t->class != ARRAY) { ! 323: trerror("%t is not an array", a); ! 324: } ! 325: eltype = t->type; ! 326: p = slist; ! 327: t = t->chain; ! 328: for (; p != NIL && t != NIL; p = p->right, t = t->chain) { ! 329: esub = p->left; ! 330: etype = rtype(esub->nodetype); ! 331: atype = rtype(t); ! 332: if (!compatible(atype, etype)) { ! 333: trerror("subscript %t is the wrong type", esub); ! 334: } ! 335: esub->nodetype = atype; ! 336: } ! 337: if (p != NIL) { ! 338: trerror("too many subscripts for %t", a); ! 339: } else if (t != NIL) { ! 340: trerror("not enough subscripts for %t", a); ! 341: } ! 342: p = alloc(1, NODE); ! 343: p->op = O_INDEX; ! 344: p->left = a; ! 345: p->right = slist; ! 346: p->nodetype = eltype; ! 347: return p; ! 348: } ! 349: ! 350: /* ! 351: * Evaluate a subscript (possibly more than one index). ! 352: */ ! 353: ! 354: long evalindex(arraytype, subs) ! 355: SYM *arraytype; ! 356: NODE *subs; ! 357: { ! 358: long lb, ub, index, i; ! 359: SYM *t, *indextype; ! 360: NODE *p; ! 361: ! 362: t = rtype(arraytype); ! 363: if (t->class != ARRAY) { ! 364: panic("unexpected class %d in evalindex", t->class); ! 365: } ! 366: i = 0; ! 367: t = t->chain; ! 368: p = subs; ! 369: while (t != NIL) { ! 370: if (p == NIL) { ! 371: panic("unexpected end of subscript list in evalindex"); ! 372: } ! 373: indextype = rtype(t); ! 374: lb = indextype->symvalue.rangev.lower; ! 375: ub = indextype->symvalue.rangev.upper; ! 376: eval(p->left); ! 377: index = popsmall(p->left->nodetype); ! 378: if (index < lb || index > ub) { ! 379: error("subscript value %d out of range %d..%d", index, lb, ub); ! 380: } ! 381: i = (ub-lb+1)*i + (index-lb); ! 382: t = t->chain; ! 383: p = p->right; ! 384: } ! 385: return i; ! 386: } ! 387: ! 388: /* ! 389: * Check that a record.field usage is proper. ! 390: */ ! 391: ! 392: LOCAL chkfield(r, f) ! 393: NODE *r; ! 394: SYM *f; ! 395: { ! 396: register SYM *s; ! 397: ! 398: chkclass(r, RECORD); ! 399: ! 400: /* ! 401: * Don't do this for compiled code. ! 402: */ ! 403: # if (!isvax) ! 404: for (s = r->nodetype->chain; s != NIL; s = s->chain) { ! 405: if (s == f) { ! 406: break; ! 407: } ! 408: } ! 409: if (s == NIL) { ! 410: error("\"%s\" is not a field in specified record", f->symbol); ! 411: } ! 412: # endif ! 413: } ! 414: ! 415: /* ! 416: * Check to see if a tree is boolean-valued, if not it's an error. ! 417: */ ! 418: ! 419: chkboolean(p) ! 420: register NODE *p; ! 421: { ! 422: if (p->nodetype != t_boolean) { ! 423: trerror("found %t, expected boolean expression"); ! 424: } ! 425: } ! 426: ! 427: /* ! 428: * Check to make sure the given tree has a type of the given class. ! 429: */ ! 430: ! 431: LOCAL chkclass(p, class) ! 432: NODE *p; ! 433: int class; ! 434: { ! 435: SYM tmpsym; ! 436: ! 437: tmpsym.class = class; ! 438: if (p->nodetype->class != class) { ! 439: trerror("%t is not a %s", p, classname(&tmpsym)); ! 440: } ! 441: } ! 442: ! 443: /* ! 444: * Construct a node for the type of a string. While we're at it, ! 445: * scan the string for '' that collapse to ', and chop off the ends. ! 446: */ ! 447: ! 448: LOCAL SYM *mkstring(str) ! 449: char *str; ! 450: { ! 451: register char *p, *q; ! 452: SYM *s, *t; ! 453: static SYM zerosym; ! 454: ! 455: p = str; ! 456: q = str + 1; ! 457: while (*q != '\0') { ! 458: if (q[0] != '\'' || q[1] != '\'') { ! 459: *p = *q; ! 460: p++; ! 461: } ! 462: q++; ! 463: } ! 464: *--p = '\0'; ! 465: if (p == str + 1) { ! 466: return t_char; ! 467: } ! 468: s = alloc(1, SYM); ! 469: *s = zerosym; ! 470: s->class = ARRAY; ! 471: s->type = t_char; ! 472: s->chain = alloc(1, SYM); ! 473: t = s->chain; ! 474: *t = zerosym; ! 475: t->class = RANGE; ! 476: t->type = t_int; ! 477: t->symvalue.rangev.lower = 1; ! 478: t->symvalue.rangev.upper = p - str + 1; ! 479: return s; ! 480: } ! 481: ! 482: /* ! 483: * Free up the space allocated for a string type. ! 484: */ ! 485: ! 486: unmkstring(s) ! 487: SYM *s; ! 488: { ! 489: dispose(s->chain); ! 490: }
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